Continuation method for PDE-constrained global optimization: Analysis and application to the shallow water equations
Abstract
This paper shows how a class of non-convex optimization problems constrained by discretized nonlinear partial differential equations may be solved to global optimality using an interior point continuation method. The solution procedure rests on a nested homotopy. The inner homotopy solves a barrier problem by driving the barrier parameter to zero. The outer homotopy deforms a convex relaxation to the original non-convex problem in a way that stays clear of bifurcations. A requirement for global optimality is that the objective is convex and that the search space remains path-connected. As a case study, a class of real-world optimization problems subject to the shallow water equations is analyzed. A benchmark as well as a practical implementation demonstrate that the approach is suitable for closed-loop non-convex model predictive control of large-scale cyber-physical systems.
Cite
@article{arxiv.1801.06507,
title = {Continuation method for PDE-constrained global optimization: Analysis and application to the shallow water equations},
author = {Jorn Baayen and Teresa Piovesan and Jesse VanderWees},
journal= {arXiv preprint arXiv:1801.06507},
year = {2020}
}
Comments
21 pages, 2 figures